JP2694637B2 - Combination valve with double pressure relief structure - Google Patents

Description

The present invention relates to a hydraulic control valve, and more particularly to a combination valve having a double relief structure. "Prior Art" A combination hydraulic valve uses a large number of spools,
It controls various functions performed by hydraulic cylinders mounted on machines such as forklift trucks and end loaders. Typically, a single spool will control the cylinder for a particular function, such as hoist (lift), tilt, or some auxiliary function. In lift truck applications, it is desirable to have greater fluid pressure available for the hoist or lift functions than is required for the tilt or auxiliary functions. Typically, a hoist or lift pressure of 2,000 psi (140 kg / cm ² ) is desired, while a tilt or auxiliary function pressure of 1,900 psi (133 kg / cm ² ) is desired. Valve systems such as those shown in Keir U.S. Pat.Nos. 3,324,881 and 3,324,882 utilize a pair of pilot valves that operate at different pressures and actuate the main relief valve. . The dual relief valve system of Kokaly U.S. Pat. No. 3,416,561 uses a single relief valve operating at two pressures. The Kokaly relief valve is used to monitor the two sides (up, down) of a single circuit. Murase et al. U.S. Pat. No. 3,811,471 also utilizes two pilot relief valves and one main relief valve. Conventionally, double pressure relief is also achieved by utilizing a special external line to supply high pressure fluid in the hoist circuit as desired. In the above conventional method and arrangement,
All require extra components, namely pilot valves and external circuits, which add to the cost of the valve. "Structure" The combination valve with dual pressure relief structure according to the present invention includes at least one valve portion, which provides high pressure fluid for hoist and lift functions. The first relief valve limits the system pressure in the valve section that requires high pressure. "Action and effect" The valve portion downstream from the high pressure valve portion performs an additional function that does not require high fluid pressure. A second relief valve, which has a lower pressure limit than the pressure of the first relief valve, limits the system pressure in the downstream valve portion. The spool position of the valve section at the boundary of the high pressure section and the low pressure section determines which relief valve is chosen to monitor the system pressure. Thus, the present invention eliminates the need for a special external line for the delivery of high pressure fluid. The present invention also provides a combination valve assembly that can monitor high pressure functions and any number of low pressure functions while utilizing only two relief valves. [Examples] Hereinafter, preferred examples of the present invention will be described with reference to the accompanying drawings. The combination valve 10 shown in FIGS. 1 and 2 consists of an inlet and outlet manifold section 12, which delivers pressurized working fluid from pump 20 to the downstream portion of the valve and returns discharge fluid to sump 24. The remaining part of the combination valve 10 consists of functional valve parts 14, 16, 18. Although the illustrated combination valve has only three valve portions beyond the inlet, it should be appreciated that more valve portions may be used to provide additional function or control. As can be seen in FIG. 2, inlet manifold portion 12 receives pressurized working fluid from pump 20 via inlet port 22 and returns discharged working fluid to reservoir 24 via outlet port 26. A relief valve 28 is located in the passage 30, which is
Monitor fluid pressure in 23. As shown in FIG. 3, the first downstream valve portion 14 is a spool.
1 is representative of an open center control valve characterized by an open center or through passage 32 that intersects a hole 34 containing 36. The valve body 14 also has a U-shaped bridge passage 38, a pair of supply passages 40, 42, and a return fluid passage 44, which can communicate with the outlet passage 46. The outlet passage 46 leads to the passage 30 at the inlet 12 and finally to the sump 24 via the outlet port 26. The curved portion of the U-shaped bridge passage 38 is a feeder branch passage 52.
And contact the feeder aisle 50 through. The feeder passage 50 is also connected to the inlet of the valve. The legs of the bridge passage 38 are spool holes at the areas 51 and 53 separated on both sides of the intermediate portion 54.
Cross 34. Therefore, the communication between the upstream and downstream parts of the open center passage through the intermediate portion 54 of the spool hole 34 is
When 36 is blocked out of the neutral position, the pressure fluid is delivered to the feeder passage 50 and from there through the feeder branch 52 to the bridge passage 38. The two supply passages 40, 42 intersect the spool hole 34 at an area axially outwardly along the spool hole 34 from an area intersecting the legs of the bridge passage 38, and thus each supply passage is Can communicate with the adjacent leg of the bridge passage through a short section of the. The discharge passage 44 includes a substantially U-shaped passage, the legs 56 and 58 of which have spool holes.
It intersects 34 near its ends and the bend communicates with the exit passage 46. Therefore, each supply passage 40, 42 can also communicate with the adjacent leg of the discharge passage through another short portion of the spool hole. According to the invention, the second downstream valve portion 16 also includes the supply port 6
0, 62 is an open center control valve, supply port 60 is a hoist lift port that provides high pressure working fluid to the hydraulic cylinders used in performing the lift or hoist function, and supply port 62 is a plug 64. It's closed. A relief valve 66, set at a lower pressure than relief valve 28, is located in passage 68 to monitor the fluid pressure in that passage. The valve portion 16 includes a specially designed spool 70 located within the bore 72. The spool 70 has lands 74, 76, 78, 80 spaced apart from each other.
And a reduced diameter portion 82, 84, 86, 88. When the spool 70 is in its neutral position, the pump 20 supplies fluid to the portions 90, 92 of the hole 72, as seen in FIG. , And then supply to the feeder passage 94. This feeder passage
94 is connected to the bridge passage 98. The fluid then travels to the open center 96, from where it either returns to the sump 24 or is utilized in the downstream valve section 18. If the return of fluid to the reservoir 24 was blocked by downstream use in the valve section 18, the pressure builds up in the feeder passage 94 and the bridge passage 98.
This pressure communicates with the passage 68 through the reduced diameter portion 88 and the relief valve
Monitored by 66. When the spool 70 moves to its left or outer position, the supply port 60 leads to the sump 24 via the constriction 82 and the discharge passage 100, and the land 76 prevents fluid from entering the supply port 60 from the bridge passage 98. Fluid from portion 90 may enter open center 96 and flow from there to downstream valve portion 18.
If fluid is utilized in the downstream valve section 18, the resulting pressure rise is monitored by the relief valve 66 as previously described. When spool 70 is moved to its rightmost or inward position, fluid is delivered to sections 90, 92 and feeder passage 94. Lands 76 prevent fluid from portion 92 from flowing to open center 96, and lands 78 prevent fluid from portion 90 from flowing to open center 96, and thus the downstream valve portion.
18 is inactive. Pressurized fluid flows from the bridge passage 98 to the supply port 60 through the reduced diameter portion 82, and the land 74 blocks discharge of the fluid from the port 60. Bridge aisle 98 to aisle 68
Fluid flow to and from the land 80 is blocked, and thus the pressure in the system is monitored by the relief valve 28. As mentioned above, the relief valve 28 is set at a pressure (2000 psi or more) that is significantly higher than the pressure of the relief valve 66 (1900 psi or less). Typically, the hoist or lift functions require higher pressure than the auxiliary functions of tilting and rotating. In the combination valve of the present invention, the hoist or lift function is provided at the supply port 60. As I explained earlier,
When fluid is provided to supply port 60, relief valve 66 is effectively removed from the system and system pressure is monitored by relief valve 28. The supply of fluid to the supply port 60 deactivates all downstream valve portions that serve an auxiliary function, thus eliminating the need for the relief valve 66. The system pressure is monitored by the relief valve 66 when the spool 70 moves to a position where the downstream valve portion, which serves an auxiliary function, allows the fluid to flow. In accordance with the present invention, the third downstream valve portion 18 is for an auxiliary function and is a typical open center control valve similar to valve portion 14. Accordingly, parts corresponding to those of valve portion 14 of valve portion 18 are indicated by the same reference numerals but with a dash. Also, any number of high pressure valve portions may be installed upstream of the valve portion 16 such that the valve portion 16 and the valve portion 18 are
It will be appreciated that one will have the pressure monitored by relief valve 28 when using a housing circuit configuration similar to. Various modes of carrying out the invention are contemplated within the scope of the following claims, which point out and distinctly claim the subject matter of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a plan view of a combination valve embodying the principle of the present invention. FIG. 2 is a sectional view taken along line 2-2 of FIG. FIG. 3 is a sectional view taken along line 3-3 of FIG. FIG. 4 is a sectional view taken along line 4-4 of FIG. FIG. 5 is a sectional view taken along the line 5-5 of FIG. In the drawing, 10 ... Combination valve 12 ... Manifold portion 14, 16, 18 ... Valve portion 20 ... Pump 22 ... Inlet port 24 ... Reservoir 26 ... Outlet port 28 ... Relief valve 30 ... Passage 34 …… Hole 36 …… Spool 38 …… Bridge passages 40, 42 …… Supply passage 44 …… Return passage 50 …… Feeder passage 52 …… Feeder branch passage 60,62 …… Supply port 64 …… Plug 68 …… Passage 70 ...... Spool 72 ...... Hole 74,76,78,80 ...... Land 82,84,86,88 ...... Reduced diameter part 98 ...... Bridge passage 96 ...... Open center

Continuation of front page    (72) Inventor James A Olsen               United States Wisconsin               53066, Okonomowak, Dorchiester                 Drive, 1177

Claims (1)

(57) [Claims] A combination valve having a dual pressure relief structure (28, 66) comprising an inlet passage (50) for receiving pressure fluid from a pump (20), a discharge passage (44) for returning fluid to a sump (24) and a downstream valve. A first valve portion (14) having means for transferring pressure fluid to the portion (16), connected downstream of the first valve portion (14) and receiving pressure fluid from the first valve portion (14) Entrance passage (90, 92, 9
4), means for transferring pressure fluid to the downstream valve portion (18) (9
6), a discharge passage (100) for returning the fluid to the reservoir (24), and a control means (70) arranged inside for controlling the flow direction of the fluid received from the first valve portion (14). And a second valve portion (16) having a supply port (60) and the first and second valve portions (14, 14) operating at a first predetermined pressure.
A first relief valve (28) for limiting the system pressure in 16) and an inlet passage connected to the downstream side of the second valve portion (16) for receiving pressure fluid from the second valve portion (16). A second relief valve (66) that has a third valve portion (18) and a second relief valve (66) that operates at a second predetermined pressure to limit the system pressure in the third valve portion (18); A combination valve, wherein any one of the relief valves for monitoring the system pressure is selected according to the position of the control means (70) in the valve portion (16). 2. The combination valve according to claim 1, wherein the first predetermined pressure is higher than the second predetermined pressure. 3. In the combination valve according to claim 1, the control means (70) can move from a neutral position to first and second operating positions (right position, left position), and the control means can move in the neutral position. One means for actuating to transfer pressure fluid to the third valve portion (18) and communicating the pressure in the third valve portion (18) to the second valve portion (16); Actuated in the (right position) to send a flow of pressure fluid to the supply port (60) of the second valve portion (16) to block the flow of pressure fluid to the third valve portion (18), Means for communicating the pressure of the second valve portion (16) with the first relief valve (28), and pressure from the supply port (60) to the sump (24) operating in the other operating position (left position) Enables the return of fluid and transfers pressure fluid to the third valve portion (18), the pressure in the third valve portion (18) The combination valve, characterized in that it comprises a means for communicating with the second relief valve (66). 4. A combination valve according to claim 1, wherein said first valve portion (14) comprises an intermediate valve portion (36) whose pressure is monitored by said first relief valve (28). A combination valve. 5. A combination valve according to claim 1, wherein said third valve portion (18) comprises at least one valve portion (36 ') whose pressure is monitored by said second relief valve (66). A combination valve characterized by including. 6. A combination valve according to claim 1, characterized in that the second relief valve (66) is arranged in the second valve part (16).